In this paper, a 3-D embedded braided piezoelectric composite structure (3-D EBPCS) is designed by embedding piezoelectric patches inside the beam of three-dimensional (3-D) braided composite material (BCM). Compared with the pasted piezoelectric composite structure, the 3-D EBPCS has the advantage of power-off self-locking, and can provide protection for the piezoelectric patches to prolong service life of the 3-D BCM in harsh environments. The representative volume element (RVE) based on hybrid mesh partitioning strategy is studied, and the mechanical parameters of the 3-D BCM are determined. The piezoelectric sensor and actuator based on the 3-D EBPCS are theoretically analyzed, and the kinematic equation and state-space model are established. The modal of the 3-D EBPCS and the effect of changes in material parameters on the natural frequency are evaluated. The proportional-integral-derivative (PID) control is applied as a piezoelectric active vibration control (AVC) method to investigate the vibration effect of the 3-D EBPCS. Finally, the effect of different embedded depth, braided angle, and piezoelectric patch position on vibration control performance is investigated. The results show that the vibration amplitude of the 3-D EBPCS effectively is greatly reduced when the proportional gain is 25, the integral gain is 1, and the differential gain is 0.1. Compared with the piezoelectric actuator in the farthest position from the fixed end, the control time is shortened by 1.82 s and the peak voltage is reduced by about 16.5% when the piezoelectric actuator is arranged in the nearest position from the fixed end. When the braided angle is increased from 20° to 40°, the vibration control time is reduced by about 11% and the peak voltage is reduced by about 2.5%. The optimal embedded depth of piezoelectric patches is 3.5 mm, with the control time of 0.71 s and the peak voltage of 145.50 V.
YangQSongCLiuS.Computerized analysis of traveling wave vibration characteristics of aviation thin-walled spiral bevel gears. J Strain Anal Eng2023; 58(5): 367–375.
2.
OzsoyMSimsNDOzturkE.Actuator saturation during active vibration control of milling. Mech Syst Signal Process2025; 224: 111942.
3.
ZhaoTYangYPanH, et al. Free vibration analysis of a spinning porous nanocomposite blade reinforced with graphene nanoplatelets. J Strain Anal Eng2021; 56(8): 574–586.
4.
Al-FurjanMSHQiZHShanL, et al. Nano supercapacitors with practical application in aerospace technology: vibration and wave propagation analysis. Aerosp Sci Technol2023; 133: 108082.
5.
LiaoYLiuPZhaoJ, et al. A novel closed-loop current control unit for decoupling vibration control of semi-active electrically interconnected suspension. Mech Syst Signal Process2024; 212: 111308.
6.
KuriakoseVMSreehariVM.Vibration and flutter analysis of damaged composite plates under thermal environment and its passive control using piezoelectric patches. Compos Part C Open2023; 11: 100361.
7.
ShenRQianXZhouJ, et al. Characteristics of passive vibration control for exponential non-viscous damping system: vibration isolator and absorber. J Vib Control2023; 29(21-22): 5078–5089.
8.
KumarJBhushanG.Analysis and improvement of driver’s ride comfort by implementing optimized hybrid semi-active vibration damper with fuzzy-PID controller. IJST Trans Mech Eng2023; 47(4): 2243–2255.
9.
PanCChenWZhouC, et al. Research on enhancing RDGs accommodation and prolonging cable life via a combination of DTR, network reconfiguration and active controls. Elect Power Syst Res2025; 239: 111223.
10.
SinghANaskarSKumariP, et al. Viscoelastic free vibration analysis of in-plane functionally graded orthotropic plates integrated with piezoelectric sensors: time-dependent 3D analytical solutions. Mech Syst Signal Process2023; 184: 109636.
11.
LyD-KTruongTTNguyenS-N, et al. A smoothed finite element formulation using zig-zag theory for hybrid damping vibration control of laminated functionally graded carbon nanotube reinforced composite plates. Eng Anal Bound Elem2022; 144: 456–474.
12.
HaoYXLiHZhangW, et al. Active vibration control of smart porous conical shell with elastic boundary under impact loadings using GDQM and IQM. Thin Wall Struct2022; 175: 109232.
13.
BeiramIHZerafatMM.Self-tuning of an interval type-2 fuzzy PID controller. IJST Trans Mech Eng2015; 39: 113–129.
14.
XieCWuYLiuZ.Modeling and active vibration control of lattice grid beam with piezoelectric fiber composite using fractional order PDμ algorithm. Compos Struct2018; 198: 126–134.
15.
XuPLanXZengC, et al. Dynamic characteristics and active vibration control effect for shape memory polymer composites. Compos Struct2023; 322: 117327.
16.
Pal SinghASharmaMSinghI. PID control of torque during drilling in GFRP laminates. Multidiscip Model Ma2014; 10(3): 346–361.
17.
AbdullahEJMajidDLRomliFI, et al. Active control of strain in a composite plate using shape memory alloy actuators. Int J Mech Mater Des2015; 11(1): 25–39.
18.
LiuYXiaoD.Shape feature controlled topology optimization of attached piezoelectric actuators for vibration control of thin-walled smart structures. Appl Math Model2023; 120: 575–594.
19.
Morteza Fatemi MoghaddamSAhmadiH. Active vibration control of truncated conical shell under harmonic excitation using piezoelectric actuator. Thin Wall Struct2020; 151: 106642.
20.
LuQWangPLiuC.An analytical and experimental study on adaptive active vibration control of sandwich beam. Int J Mwch Sci2022; 232: 107634.
21.
JalaliMRShavalipourASafarpourM, et al. Frequency analysis of a graphene platelet–reinforced imperfect cylindrical panel covered with piezoelectric sensor and actuator. J Strain Anal Eng2020; 55(5-6): 181–196.
22.
Sabzikar BoroujerdyMEslamiMR. Thermal buckling of piezoelectric functionally graded material deep spherical shells. J Strain Anal Eng2014; 49(1): 51–62.
23.
NguyenNVLeeJNguyen-XuanH.Active vibration control of GPLs-reinforced FG metal foam plates with piezoelectric sensor and actuator layers. Compos B Eng2019; 172: 769–784.
24.
WangBHuangfuGWangJ, et al. Lead-free piezoceramic macro-fiber composite actuators toward active vibration control systems. J Materiomics2024; 10(1): 78–85.
25.
SohnJWChoiS-BLeeC-H.Active vibration control of smart hull structure using piezoelectric composite actuators. Smart Mater Struct2009; 18(7): 074004.
26.
DattaP.Active vibration control of axially functionally graded cantilever beams by finite element method. Mater Today Proc2021; 44: 2543–2550.
27.
ShivashankarPGopalakrishnanS.Review on the use of piezoelectric materials for active vibration, noise, and flow control. Smart Mater Struct2020; 29(5): 053001.
28.
HaghdoustPConteALCinquemaniS, et al. Investigation of shape memory alloy embedded wind turbine blades for the passive control of vibrations. Smart Mater Struct2018; 27(10): 105012.
29.
YangCYeTQiuM, et al. A semi-analytical framework for comprehensive vibration analysis of segment-coupled plates with embedded acoustic black holes. Thin Wall Struct2023; 184: 110517.
30.
MengQQianCSunZY, et al. A homogeneous domination output feedback control method for active suspension of intelligent electric vehicle. Nonlinear Dyn2021; 103(2): 1627–1644.
31.
LiDJiangJLiuW, et al. A new mechanism for the vibration control of large flexible space structures with embedded smart devices. IEEE/ASME Trans Mechatron2015; 20(4): 1653–1659.
32.
KocherlaADuddiMSubramaniamKVL. Smart embedded PZT sensor for in-situ elastic property and vibration measurements in concrete. Measurement2021; 173: 108629.
33.
TakácsGBatistaGGulanM, et al. Embedded explicit model predictive vibration control. Mechatronics2016; 36: 54–62.
34.
GonçalvesJFDe LeonDMPerondiEA.Topology optimization of embedded piezoelectric actuators considering control spillover effects. J Sound Vib2017; 388: 20–41.
35.
QiRWangLZhouX, et al. Embedded piezoelectric actuation method for enhanced solar wings vibration control. Int J Mwch Sci2024; 274: 109271.
36.
LiuTZhengHGuoX, et al. Internal resonance and nonlinear dynamics of an axially moving FGM sandwich cylindrical shell. Thin Wall Struct2025; 208: 112783.
37.
ZhengYDuanJLiuT, et al. Nonlinear vibrations of three-phase composite truncated conical shells affected by complex factors under 1:1 internal resonance. Commun Nonlinear Sci2025; 140: 108427.
38.
LiuTZhangWMaoJJ, et al. Nonlinear breathing vibrations of eccentric rotating composite laminated circular cylindrical shell subjected to temperature, rotating speed and external excitations. Mech Syst Signal Process2019; 127: 463–498.
39.
JiaYWeiXXuL, et al. Multiphysics vibration FE model of piezoelectric macro fibre composite on carbon fibre composite structures. Compos B Eng2019; 161: 376–385.
40.
LiuTZhengHYZhangW, et al. Nonlinear forced vibrations of functionally graded three-phase composite cylindrical shell subjected to aerodynamic forces, external excitations and hygrothermal environment. Thin Wall Struct2024; 195: 111511.
41.
AngelettiFTortoriciDLaurenziS, et al. Vibration control of innovative lightweight thermoplastic composite material via smart actuators for aerospace applications. Appl Sci2023; 13: 179715.
42.
ZhangWZhengHLiuT, et al. Nonlinear resonant responses and chaotic dynamics of three-dimensional braided composite cylindrical shell. Aerosp Sci Technol2024; 148: 109099.
43.
MaXWeiG.Numerical prediction of effective electro-elastic properties of three-dimensional braided piezoelectric ceramic composites. Compos Struct2017; 180: 420–428.
44.
ZhangGSWeiGFMengXX, et al. Electro-mechanical coupling analysis of three-dimensional embedded braided composite piezoelectric vibration energy harvester. Zamm Z Angew Math Me2024; 104: e202300699.
45.
SunMZhangDQianK.Visualization and quantification of low-velocity impact damage of three-dimensional braided CFRP composites by micro-computed tomography. Heliyon2022; 8: e12110.
46.
SunXQiaoJWeiG, et al. Numerical simulation of electromechanical coupling properties of three-dimensional braiding piezoelectric composite actuator. Results Phys2021; 23: 104056.
47.
GongZGSongMWeiGF, et al. Design and analysis of a 3-D braided composite piezoelectric thin sheet micromotion platform. Zamm Z Angew Math Me2025; 105: e70067.
48.
MengXWeiGLiA.Vibration characteristics of force–electric–thermal coupling for three-dimensional braided piezoelectric composite energy harvester. Int J Appl Mech2023; 15(04): 2350020.
49.
KumarAKiranRChauhanVS, et al. Piezoelectric energy harvester for pacemaker application: a comparative study. Mater Res Express2018; 5(7): 075701.
